Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

(With type erasure, I mean hiding some or all of the type information regarding a class, somewhat like Boost.Any.)
I want to get a hold of type erasure techniques, while also sharing those, which I know of. My hope is kinda to find some crazy technique that somebody thought of in his/her darkest hour. :)

The first and most obvious, and commonly taken approach, that I know, are virtual functions. Just hide the implementation of your class inside an interface based class hierarchy. Many Boost libraries do this, for example Boost.Any does this to hide your type and Boost.Shared_ptr does this to hide the (de)allocation mechanic.

Then there is the option with function pointers to templated functions, while holding the actual object in a void* pointer, like Boost.Function does to hide the real type of the functor.

For now, because both examples are rather lengthy, I'll link to Ideone with class and example code to both implementations. If there is a wish to just include the source in this question, please leave a comment saying so. :) The code can be found here. (The examples are by no means complete or actually safe-to-use at all. They shall just demonstrate the type erasure technique.)

So, for my actual question:
What other type erasure techniques do you know of? Please provide them, if possible, with an example code, use cases, your experience with them and maybe links for further reading. That would be really great and thanks in advance for all answers!

(Since I wasn't sure wether to add this as an answer, or just edit the question, I'll just do the safer one.)
Another nice technique to hide the actual type of something without virtual functions or void* fiddling, is the one GMan employs here, with relevance to my question on how exactly this works.

share|improve this question
By "type erasure", are you really referring to "polymorphism"? I think "type erasure" has a somewhat specific meaning, which is usually associated with e.g. Java generics. –  Oli Charlesworth Mar 27 '11 at 16:08
@Oli: Type erasure can be implemented with polymorphism, but that's not the only option, my second example shows that. :) And with type erasure I just mean, that your struct isn't dependend on a template type for example. Boost.Function doesn't care if you feed it a functor, a function pointer, or even a lambda. Same with Boost.Shared_Ptr. You can specifiy an allocator and deallocation function, but the actual type of the shared_ptr doesn't reflect this, it will always be the same, shared_ptr<int> for example, unlike standard container. –  Xeo Mar 27 '11 at 16:12
@Matthieu: I consider the second example also type safe. You always know the exact type you're operating on. Or am I missing something? –  Xeo Mar 27 '11 at 16:18
@Matthieu: You're right. Normally such an As(s) function wouldn't be implemented that way. Like I said, by no means safe-to-use! :) –  Xeo Mar 27 '11 at 16:23
Added a bounty in hope of somehow finding some neat techniques. :< –  Xeo May 12 '11 at 0:55
show 13 more comments

5 Answers

All type erasure techniques in C++ are done with function pointers (for behaviour) and void* (for data). The "different" methods simply differ in the way they add semantic sugar. Virtual functions, e.g., are just semantic sugar for

struct Class {
    struct vtable {
        void (*dtor)(Class*);
        void (*func)(Class*,double);
    } * vtbl

iow: function pointers.

That said, there's one technique I particularly like, though: It's shared_ptr<void>, simply because it blows the minds off of people who don't know you can do this: You can store any data in a shared_ptr<void>, and still have the correct destructor called at the end, because the shared_ptr constructor is a function template, and will use the type of the actual object passed for creating the deleter by default:

    const shared_ptr<void> sp( new A );
} // calls A::~A() here

Of course, this is just the usual void*/function-pointer type erasure, but very conveniently packaged.

share|improve this answer
Coincidentally, I had to explain the behaviour of shared_ptr<void> to a friend of mine with an example implementation just some days ago. :) It really is cool. –  Xeo May 18 '11 at 12:36
add comment

Fundamentally, those are your options: virtual functions or function pointers.

How you store the data and associate it with the functions can vary. For example, you could store a pointer-to-base, and have the derived class contain the data and the virtual function implementations, or you could store the data elsewhere (e.g. in a separately allocated buffer), and just have the derived class provide the virtual function implementations, which take a void* that points to the data. If you store the data in a separate buffer, then you could use function pointers rather than virtual functions.

Storing a pointer-to-base works well in this context, even if the data is stored separately, if there are multiple operations that you wish to apply to your type-erased data. Otherwise you end up with multiple function pointers (one for each of the type-erased functions), or functions with a parameter that specifies the operation to perform.

share|improve this answer
So, in other words the examples I gave in the question? Though, thanks for writing it up like this, especially w.r.t. to the virtual functions and multiple operations on the type-erased data. –  Xeo May 17 '11 at 17:28
There are at least 2 other options. I am composing an answer. –  John Dibling May 17 '11 at 18:57
add comment

I would also consider (similar to void*) the use of "raw storage": char buffer[N].

In C++0x you have std::aligned_storage<Size,Align> for this.

You can store anything you want in there, as long as it's small enough and you deal with the alignment properly.

share|improve this answer
Well yeah, Boost.Function actually uses a combination of this and the second example I gave. If the functor is small enough, it stores it internally inside the functor_buffer. Good to know about std::aligned_storage though, thanks! :) –  Xeo Mar 27 '11 at 16:21
add comment

See this series of posts for a (fairly short) list of type erasure techniques and the discussion about the trade-offs: Part I, Part II, Part III, Part IV.

The one I haven't seen mentioned yet is Adobe.Poly, and Boost.Variant, which can be considered a type erasure to some extent.

share|improve this answer
add comment

In C++ you shouldn't really do type erasure. C++ does everything like this automatically. For example, const works like that in C++. Const has no effect on the generated code and thus was erased from the compiled program.

Instead of type erasure, a common pattern is to move the type to runtime via void* and typeid(T).

share|improve this answer
I think you don't understand the meaning of type erasue. :| Look at the two example codes provided by the Ideone link in my question and at my discussion with Oli in the comments. Also, void* is a type erasure technique, again, see my example codes. –  Xeo May 15 '11 at 18:08
@xeo that's what happens when you use a term like type erasure, which has a specific meaning, as if it meant something else. Boost::any doesn't do compile-time type erasure, it just throws away some information at runtime. –  amalloy May 16 '11 at 5:17
@amalloy I'm with Xeo on that one; if you google "c++ type erasure" you can see the term is well understood in the C++ community. It's unfortunate that it's shared with other usages. (Probably to blame to a lack of imagination). –  Luc Danton May 16 '11 at 17:28
@amalloy: That's not Xeo's fault. The term is in general usage for this technique. –  sbi May 17 '11 at 17:08
The supply of combinations of words is infinite, yet the supply of mots justes is extremely limited. There aren't enough to go around. –  Steve314 Jul 26 '11 at 12:06
show 3 more comments

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.